JP2007244807A - Bathroom sauna apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bathroom sauna apparatus carrying out humidification by mist in an air conduit, wherein efficient humidification is allowed without giving an unpleasant feeling to a bathing person by blowing out large-diameter droplets into a bathroom, with comparatively simple constitution. <P>SOLUTION: The bathroom sauna apparatus 1 is provided with: a suction port 103 for sucking air in the bathroom; the air conduit 104 for carrying the sucked air; a cross flow fan 107 for sucking and blowing air in the bathroom; a humidification part 15 for humidifying air passing through the inside of the air conduit 104; and a blow out port 102 for jetting humidified air into the bathroom. Fine droplets sprayed from a jetting nozzle 105 provided in the humidification part 15 is made smaller in a sprayed droplet crushing part 16 arranged in a spraying direction. Thus the apparatus 1 for obtaining sufficient humidification amount without blowing out the large-diameter droplets into the bathroom, with comparatively simple constitution, is obtained. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a bathroom sauna apparatus in which the interior of a bathroom is used as a sauna space by heating and humidifying the interior of the bathroom.

  Conventionally, this type of bathroom sauna device has a heated and humidified air in the bathroom by connecting the air outlet and the air inlet provided in the bathroom with an air passage, and exposing the humidifier to the air passage to blow out hot water. Is known (see, for example, Patent Document 1).

  Hereinafter, the bathroom sauna apparatus will be described with reference to FIG.

  As shown in FIG. 10, this bathroom sauna apparatus is provided with an outlet 102 and an inlet 103 in the bathroom 101, and the inlet 103 is connected to the outlet 102 through an air passage 104, and a spray nozzle 105 is provided in the air passage 104. , The spray nozzle 105 is connected to the water heater 106, and the cross flow fan 107 is interposed in the suction port 103.

  The warm air generator 108 provided in the air passage 104 is provided with an intake communication port 110, an outlet communication port 111, and a drain port 112 in the case main body 109, and the intake air communication port 110 and the outlet communication port 111 are connected to the air passage 104. A plurality of ventilation guide plates 113 are arranged in the case main body 109 to form a bypass mixing chamber 114, and the intake communication port 110 and the blowout communication port 111 are connected to each other through the bypass mixing chamber 114. The spray nozzle 105 faces the intake communication port 110 of the bypass mixing chamber 114 and communicates therewith.

In the bathroom sauna apparatus configured as described above, the hot water spray sprayed by the spray nozzle 105 is mixed with air in the bypass mixing chamber 114 to become humidified warm air, and is sent into the bathroom 101 from the outlet 102. It is.
JP-A-2-264659 (page 1-4, FIG. 1)

  In such a conventional bathroom sauna apparatus, when spraying in the air passage and humidifying, a relatively large diameter water droplet remains, the humidification cannot be performed efficiently, and an effective humidification amount cannot be obtained. Therefore, it is required to produce finer water droplets and to send out more water droplets.

  In addition, there is a problem in that large-sized water droplets are ejected from the blowout outlet, which may cause discomfort to the bather due to the feeling of water droplets, and it is required to suppress the generation of large-sized water droplets or to efficiently collect them. Has been. In the conventional configuration, measures such as installing a plurality of large ventilation guide plates have been taken in order to solve such a problem, but a new problem that the ventilation resistance increases or the configuration becomes complicated. Will occur.

  The present invention solves the above-mentioned problem, and even when spraying in the air passage and humidifying, relatively small water droplets are generated to increase the amount of humidification, and the interior of the bathroom is relatively large with a relatively simple configuration. The purpose is to obtain a bathroom sauna device that does not blow out water droplets of diameter.

  In order to achieve the above object, the first solution taken by the present invention is a suction port for sucking in the air in the bathroom, an air passage for conveying the sucked air, and sucking the air in the bathroom, In the bathroom sauna apparatus provided with the blowing means for blowing air, the humidifying means for humidifying the air passing through the air passage, and the outlet for blowing the humidified air into the bathroom, the humidifying means is The sprayed water droplet is a method of humidifying the air by spraying humidified water on the air passing through the air passage, and the water droplets after spraying collide with the direction of spraying the humidified water in the humidifying means to make the water droplets finer A crushing part is provided.

  By this means, it becomes possible to break up the fine water droplets sprayed from the spraying means into finer water droplets in the bathroom sauna apparatus, so that the amount of humidification can be increased and large diameter water droplets are not blown out. A bathroom sauna device is obtained.

  Moreover, the 2nd solution means which this invention took is the said spraying water droplet crushing part in the spraying direction of a spraying means, and the said spraying water droplet crushing part is made into the shape with the inclination with respect to the horizontal surface.

  By this means, drainage on the surface of the sprayed water droplet crushing part is improved, the solid wall surface of the sprayed water drop crushing part is easily exposed, and ideal crushing is performed on the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. Therefore, the amount of humidification can be increased, and a bathroom sauna apparatus that does not blow out large-diameter water droplets can be obtained.

  Moreover, the 3rd solution means which this invention took is that the said spraying water droplet crushing part exists in the spraying direction of a spraying means, and the said spraying water drop crushing part makes a comb-tooth shape.

  This means improves the drainage on the surface of the sprayed water droplet crushing part, makes it easy to expose the solid wall surface of the sprayed water droplet crushing part, and is ideal for the contact surface between the fine water droplet sprayed from the spraying means and the sprayed water droplet crushing member. Crushing is possible. In addition, since it is possible to carry more crushed water droplets crushed by passing the air between the comb teeth to the outlet, the amount of humidification can be increased and large diameter water droplets can be blown out. A bathroom sauna device without any problem is obtained.

  According to a fourth means of the present invention, the sprayed water droplet crushing portion is in the spraying direction of the spraying means, and the sprayed water droplet crushing portion has a shape in which a protrusion is raised from a plane.

  This means that the water drainage on the surface of the sprayed water droplet crushing part is improved and the solid wall surface of the sprayed water droplet crushing part is easily exposed, so it is ideal for the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. Crushing becomes possible. In addition, by allowing the water droplets after spraying to collide with the projections, the diffusibility of the fine water droplets after the collision is increased, and more fine water droplets can be transported to the outlet, so that the amount of humidification can be increased. A bathroom sauna device without blowing out large-diameter water droplets can be obtained.

  Further, a fifth solving means taken by the present invention is that the surface of the sprayed water droplet crushing part is water repellent.

  This means that the water drainage on the surface of the sprayed water droplet crushing part is improved and the solid wall surface of the sprayed water droplet crushing part is easily exposed, so it is ideal for the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. Therefore, the amount of humidification can be increased, and a bathroom sauna apparatus that does not blow out large-diameter water droplets can be obtained.

  Moreover, the 6th solution means which this invention took is that the said sprayed water droplet crushing part vibrates finely.

  By this means, it is possible to further enhance the water droplet crushing effect in the sprayed water droplet crushing section, so that the amount of humidification can be increased and a bathroom sauna apparatus that does not blow out large diameter water droplets can be obtained.

  According to the present invention, even when spraying in the air passage and humidifying, relatively small water droplets are generated to increase the amount of humidification, and large diameter water droplets are blown into the bathroom with a relatively simple configuration to the bather. It is possible to provide a bathroom sauna device that does not cause discomfort.

  The invention described in claim 1 of the present invention includes a suction port for sucking in the air in the bathroom, a blower passage for transporting the sucked air, and a blowing means for sucking and blowing the air in the bathroom, In the bathroom sauna apparatus provided with a humidifying means for humidifying the air passing through the air passage and a blower outlet for ejecting the humidified air to the bathroom, the humidifying means is an air passing through the air passage. This is a method of humidifying air by spraying humidified water, and provided with a sprayed water droplet crushing unit for making the water droplets fine by colliding the water droplets after spraying in the humidifying water spraying direction in the humidifying means. By this means, it becomes possible to break up the fine water droplets sprayed from the spraying means into finer water droplets in the bathroom sauna apparatus, so that the amount of humidification can be increased and large diameter water droplets can be blown out. Not bathroom sauna equipment It has the effect of obtaining.

  Further, the invention according to claim 2 of the present invention is such that the sprayed water droplet crushing portion is in the spraying direction of the spraying means, and the sprayed water droplet crushing portion has a shape having a gradient with respect to a horizontal plane. Since the drainage performance on the surface of the sprayed water droplet crushing part is improved by the means and the solid wall surface of the sprayed water droplet crushing part is easily exposed, it is ideal for the contact surface between the fine water droplet sprayed from the spraying means and the sprayed water droplet crushing member. Since crushing is possible, the amount of humidification can be increased, and a bathroom sauna apparatus that does not blow out large-diameter water droplets can be obtained.

  According to a third aspect of the present invention, the sprayed water droplet crushing portion is in the spraying direction of the spraying means, and the sprayed water droplet crushing portion has a comb-tooth shape. Since the drainage on the surface of the crushing part is improved and the solid wall surface of the sprayed water droplet crushing part is easily exposed, ideal crushing is possible on the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. Become. In addition, since it is possible to carry more crushed water droplets crushed by passing the air between the comb teeth to the outlet, the amount of humidification can be increased and large diameter water droplets can be blown out. A bathroom sauna device without any problem is obtained.

  In the invention according to claim 4 of the present invention, the sprayed water droplet crushing part is in the spraying direction of the spraying means, and the sprayed water droplet crushing part has a shape in which a protrusion is raised from a flat surface. This improves the drainage on the surface of the sprayed water droplet crushing part and makes it easier to expose the solid wall surface of the sprayed water droplet crushing part. Therefore, ideal crushing is performed on the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. Is possible. In addition, by causing the water droplets after spraying to collide with the protrusions, the degree of diffusion of the fine water droplets after the collision is increased, and it becomes possible to carry more fine water droplets to the outlet, so that the amount of humidification can be increased. A bathroom sauna device without blowing out large-diameter water droplets can be obtained.

  Further, the invention according to claim 5 of the present invention is such that the surface of the sprayed water droplet crushing part is water-repellent. By this means, drainage on the surface of the sprayed water droplet crushing part is improved, and the sprayed water droplet crushing part is This makes it easy to expose the solid wall surface, so that ideal crushing is possible on the contact surface between the fine water droplets sprayed from the spraying means and the sprayed water droplet crushing member. A bathroom sauna device without blowing out is obtained.

  Further, in the invention according to claim 6 of the present invention, the sprayed water droplet crushing portion is finely vibrated, and this means can further enhance the water droplet crushing effect in the sprayed water droplet crushing portion. A bathroom sauna apparatus that can increase the amount and does not blow out large-diameter water droplets can be obtained.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

(Embodiment 1)
Embodiment 1 of the present invention will be described below with reference to the drawings. In addition, the same code | symbol is used about the same part as a prior art example, and detailed description is abbreviate | omitted.

  First, a schematic configuration of the bathroom sauna apparatus in the present invention will be described.

  FIG. 1 is a schematic diagram showing a schematic configuration of a bathroom sauna apparatus according to an embodiment of the present invention. As shown in FIG. 1, the bathroom sauna apparatus 1 includes an exterior body 2 and a front panel 3 that form an outer shell, a sauna module 4 that sucks air in the bathroom, heats and humidifies it, and then blows it back into the bathroom, and a plate heat exchanger 5. The ventilation unit 8 is provided on one surface of the exterior body 2 and connected to the opening 7 communicating with the air passage, and the control device 9 controls these components. Each specific configuration will be described below.

  As shown in FIG. 2, the front panel 3 that forms the bathroom side surface of the exterior body 2 is a suction port 103 for sucking air in the bathroom, and for blowing out the heated and humidified air to the outside of the bathroom sauna device 1. An air outlet 102 is provided. Moreover, the filter 10 is provided in the sauna module 4 side of the suction inlet 103, and it has the structure which prevents the penetration | invasion of a fine dust and dust when circulating the air in a bathroom. Further, a louver 11 for changing the blowing direction of the heated and humidified air is provided at the outlet 102, and the louver 11 is a louver connected to a control device 9 (not shown in FIG. 2). By operating freely by the drive motor 12, the blowing direction can be varied in an arbitrary direction.

  As shown in FIG. 3, in the sauna module 4, an air passage 104 that connects the suction port 103 and the air outlet 102 of the front panel 3 is provided, and a control provided on the air inlet 103 side of the air passage 104. Air is blown into the sauna module 4 by rotation of a cross flow fan 107 as a blowing means connected to a motor 13 whose rotation speed can be freely changed by a device 9 (not shown in FIG. 3). An upstream side of the cross flow fan 107 is provided with a coil 14 which is a heat exchanger for air heating as a heating means, and hot water is supplied to the coil 14 from a heat supply unit 6 (not shown in FIG. 3). By supplying, the air flowing in from the bathroom through the coil 14 is heated, and it becomes possible to blow hot air. A humidifying unit 15 is provided on the downstream side of the cross flow fan 107 in the air blowing path 104. Hot water (for example, 40 to 80 ° C.) is supplied from the heat supply unit 6 to the ejection nozzle 105 as a spraying means provided in the humidification unit 15, and the supplied hot water is sprayed from the ejection nozzle 105 as fine water droplets. At this time, the sprayed water droplet crushing unit 16 is provided in front of the spraying direction, and the sprayed water droplet is changed into a finer shape using the sprayed water droplet crushing unit 16. The sprayed water droplet crushing portion 16 has a shape having a gradient with respect to a horizontal plane when installed in the air passage. According to this shape, drainage is good, and excess water does not stay at the location where the hot water sprayed from the ejection nozzle 105 and the sprayed water droplet crushing portion 16 collide, so that the solid wall surface is exposed and disturbed by the excess water. Water droplets can be crushed without any damage. At this time, the larger the installation gradient, the better. However, it is desirable to ensure that a gradient of 5 ° or more is ensured, so that excess water at the collision portion between the sprayed hot water and the sprayed water droplet crushing portion 16 can be surely drained. It becomes. Since the surface of the sprayed water droplet crushing portion 16 is water-repellent with a silicon-based thin film formed thereon, the drainage performance is improved. Further, as shown in FIG. 4, the sprayed water droplet crushing portion 16 has a comb-like shape in which flat plates 18 having a plate thickness of about 2 mm are arranged on the crushing portion plane 17 at intervals similar to the plate thickness of the flat plate 18. The drainage is further improved, and the blown air passes through the gaps between the comb teeth, so that more fine water droplets can be conveyed to the outlet 102. At that time, if the sprayed water droplet crushing portion 16 is vibrated at a frequency of about 1 MHz to 3 MHz by an ultrasonic oscillator, the relative speed between the sprayed water droplet and the sprayed water droplet crushing portion 16 is increased, and the water droplet can be broken into finer water droplets. It becomes possible. Here, with respect to fine water droplets (for example, a water droplet diameter of 100 μm or less), the water droplets that are carried along with the air to be blown to the outlet 102 to humidify the interior of the bathroom and could not be crushed into fine water droplets, go to the drainage section 112 Head. Among the fine water droplets carried with the blown air, water droplets having a relatively large water droplet diameter (for example, a water droplet diameter of 10 to 100 μm) are collected by an eliminator 19 as a water droplet collecting means provided on the outlet 102 side of the humidifying unit 15. To the drainage section 112. Fine water droplets (water droplet diameter of 10 μm or less) that have passed through the eliminator 19 are supplied to the bathroom from the air outlet 102 together with the air heated by the coil 14, and heat and humidify the interior of the bathroom. The eliminator 19 is made of a coarse mesh material, and does not require a large-scale structure such as a meandering air passage using the conventional ventilation guide plate 113, and the pressure loss can be made relatively small. Moisture toward the drainage part 112 passes through the drainage pipe 20 connected to the drainage part 112 and is drained outside the apparatus. The drainage part 112 is provided at the lowermost part of the humidification part 15 and has a slope on the bottom surface so that the drainage pipe connection part becomes the lowermost end so that excess water does not stay in the humidification part. At this time, the larger the angle of the drainage gradient on the bottom surface, the better. However, it is desirable to ensure that the excess water in the humidifying section is drained by ensuring a gradient of 5 ° or more. Similarly, the drainage pipe 20 connected to the outside of the apparatus can be installed with an equivalent gradient of 5 ° or more to prevent the excess water from staying in the apparatus. Further, the drainage unit 112 is provided with a float switch 21. When the water level rise of the drainage unit 112 is detected and the predetermined water level is exceeded, the control device 9 stops the water supply to the ejection nozzle 105 to humidify. Water leakage from the part 15 is prevented.

  In the heat supply unit 6 shown in FIG. 5, the circulating hot water supplied from the heat source is branched by the branching unit 22 into two paths, a heating hot water circulation circuit 23 and a humidifying hot water circulation circuit 24. The heating hot water circulation circuit 23 is connected to the coil 14 and heats the coil 14. As shown in FIG. 6, the coil 14 includes a water pipe 29 through which the heating hot water supplied from the hot water circulation circuit 23 circulates, and a heat transfer fin 30 provided on the outer wall portion of the water pipe 29. The heat transfer fins 30 are heated by the high-temperature heating circulating hot water flowing through the water flow pipe 29, and air is circulated through the heat transfer fins 30 to exchange heat with the air to heat the air. The humidifying hot water circulation circuit 24 is connected to the plate heat exchanger 5 to heat the plate heat exchanger 5. As shown in FIG. 7, the plate heat exchanger 5 is configured by alternately arranging two paths, a high temperature side path 32 and a low temperature side path 33, which are blocked by the heat transfer wall 31. Heat is exchanged through the heat transfer wall 31 to heat the liquid on the low temperature side by circulating the humidified water used for humidification in the opposite direction in the low temperature side path 33 while flowing through the path 32. The circulating hot water that has exited the coil 14 and the plate heat exchanger 5 passes through the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 again and flows into the junction 26, and the circulating hot water that has joined the one path passes to the heat source. Then, it is heated again and the supply is repeated. The tap water supplied from the liquid supply means passes through the water supply path 25 and is connected to the low temperature side path 33 of the plate heat exchanger 5. The tap water exiting the plate heat exchanger 5 flows again into the ejection nozzle 105 through the water supply path 25. The tap water in the water supply path 25 that has been subjected to heat exchange and becomes high temperature is sprayed from the ejection nozzle 105 to form fine hot water droplets, and is blown into the bathroom together with the heated bathroom air. The hot water that has flowed into the coil 14 through the heating hot water circulation circuit 23 exchanges heat with the air in the bathroom that passes through the air passage 104 by the cross flow fan 107 inside the coil 14. Heats the interior of the bathroom by blowing out the air in the bathroom, which has become hot after heat exchange, into the bathroom. In addition, a thermal valve 27 for blocking the circulation is provided in the two flow paths of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24, and the flow rate of the circulating hot water flowing into the coil 14 and the plate heat exchanger 5 is provided. The amount of heating and humidification can be changed by adjusting. The thermal valve 27 is a valve that opens and closes the valve by increasing the temperature of the valve support connected to the valve body by supplying electric power and expanding and deforming the valve support. Further, an electromagnetic valve 28 is provided on the upstream side of the plate heat exchanger 5 on the water supply path 25, and the supply amount of the humidified water can be changed by controlling the opening and closing of the water supply. The electromagnetic valve 28 is a valve that opens and closes a valve that uses electromagnetic force by an electrical signal.

  The ventilation unit 8 shown in FIG. 8 includes a ventilation fan 34 for sucking in bathroom air into the ventilation unit 8 and an exhaust duct 35 which is an air exhaust path, and an opening provided on one surface of the exterior body 2. The part 7 and the opening 7 are connected via a damper 36 for changing the opening area. The damper 36 is normally closed during the sauna operation, but can be opened and closed by a damper driving motor 37 connected to the control device 9 (not shown in FIG. 8), and the ventilation fan 34 is rotated and the damper is rotated. By opening 36, the air in the bathroom is ventilated into the ventilation unit 8 from the suction port 103, and is ventilated from the exhaust duct 35 to ventilate the bathroom. The adjustment of the ventilation amount is performed by changing the opening area of the damper 36 and controlling the rotational speed of the ventilation fan 34, and a necessary ventilation amount is realized by a combination thereof.

  When the sauna operation is started, the motor 13 in the sauna module 4 is operated to rotate the cross flow fan 107, and the air in the bathroom is sucked from the suction port 103, passes through the air blowing path 104, and again enters the bathroom from the air outlet 102. The air in the bathroom circulates by flowing into the room. At that time, the thermal valve 27 that is an opening and closing means of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 and the electromagnetic valve 28 that is an opening and closing means of the water supply path 25 are opened, and heating and humidification are started in the apparatus. . At this time, the louver 11 provided on the front panel 3 is opened, and the blowing direction of the heated and humidified air is controlled. When a certain amount of time has elapsed and the temperature and humidity in the bathroom reach a predetermined value, the number of revolutions of the motor 13 is changed, and the amount of heating and humidification is changed. After that, when a certain amount of time has passed and the temperature and humidity in the bathroom exceed a predetermined value, the number of rotations of the motor 13 is changed to adjust the temperature and humidity in the bathroom, and the heating hot water circulation circuit 23 and the humidification hot water circulation are changed. The temperature and humidity in the bathroom are controlled by repeatedly opening and closing the thermal valve 27 provided in the circuit 24 and the electromagnetic valve 28 provided in the water supply path 25. When the sauna operation is stopped, the operation of the motor 13 in the sauna module 4 is stopped, and the thermal valve 27 provided in the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 and the electromagnetic valve 28 provided in the water supply path 25 are provided. close. Thereafter, in order to perform ventilation operation for drying in the bathroom, the damper 36 provided at the connecting portion of the exterior body 2 and the ventilation unit 8 is opened, and the ventilation fan 34 in the ventilation unit 8 is rotated to rotate the bathroom sauna. The air in the bathroom that flows in from the suction port 103 of the apparatus 1 is discharged from the exhaust duct 35 to the outside of the bathroom.

  By performing the operation as described above, the inside of the sauna target room (bathroom) is in a high-temperature and high-humidity state (about 40 ° C./80%), and can be in a mist sauna state that encourages bathers to sweat. Become. In addition, by forming the humidifying unit 15 with the configuration as in the present embodiment, water droplets having a large diameter are collected and compared in the air passage 104 even without a large configuration like a conventional meandering air channel. Only small water droplets can be blown into the bathroom.

  In this embodiment, the sauna target room has been described as a bathroom. However, if the problem such as condensation in a high humidity space can be solved, the room is not limited to the bathroom, and a space dedicated to the sauna is used. Even if the configuration is provided separately, there is no difference in the function and effect.

  In the present embodiment, the motor 13 for driving the cross flow fan 107 is the motor 13 whose rotational speed can be freely changed by the control device 9, but can be changed to at least two kinds of rotational speeds. There is no need to make any difference in the effects. Desirably, the motor is preferably a motor that can linearly change the rotational speed to an arbitrary rotational speed. Further, when the operation is performed under constant conditions without changing various settings, there is no problem even if the motor is driven only at a constant rotational speed, and there is no difference in the operation effect.

  In the present embodiment, the air in the bathroom is blown into the air passage 104 using the cross flow fan 107 as the air blowing means. If the air flow, power consumption, noise, vibration, etc. are satisfied, the sirocco Even if it is a fan of another type, such as a fan, a turbo fan, or a propeller fan, there is no problem and no difference is produced in its operation effect.

  Further, in the present embodiment, the fin tube type coil 14 is used as a heating means for heating the blown air. However, there is no problem even if other heating means is used as long as the blown air can be sufficiently heated. Even if a heater or other heat source is used in front of the cross flow fan 107, there is no difference in the function and effect.

  Moreover, in this Embodiment, it was set as the structure which humidifies by spraying warm water in the humidification part 15, However When a bathroom is small (about 0.5 tsubos) and does not require so much humidification, it is normal temperature Even if tap water (about 20 ° C) is used, there will be no difference in its effects. Desirably, it will be ejected so that the bathroom has the desired temperature and humidity according to the size of the bathroom and the temperature atmosphere outside the bathroom. It is desirable to appropriately set the temperature of the humidified water ejected from the nozzle 105.

  In the present embodiment, the sprayed water droplet crushing portion 16 has a comb-teeth shape in which flat plates 18 having a plate thickness of about 2 mm are arranged on the crushing portion plane 17 at intervals similar to the plate thickness of the flat plate 18. There is no problem as long as the drainage and the air permeability between the flat plates are good, and there is no difference in the function and effect even when the flat plate has a different thickness.

  Further, in the present embodiment, the surface of the sprayed water droplet crushing portion 16 is made water-repellent by forming a silicon-based thin film, but surplus is present at the location where the hot water sprayed from the ejection nozzle 105 collides with the sprayed water droplet crushing portion 16. There is no problem even if other means are used as long as the water can be prevented from staying, and even if a method of forming a Teflon (registered trademark) -based thin film or a resin having water repellency is used, the effect is also achieved. Does not make a difference.

  In the present embodiment, the sprayed water droplet crushing unit 16 vibrates at a frequency of about 1 MHz to 3 MHz by the ultrasonic oscillator. However, if the water droplet can be crushed to the required size, the frequency within that range can be used. There is no problem even if other means are used, and even if a method using a motor or a linear drive method is used, there is no difference in the operation effect.

  In the present embodiment, the diameter of the water droplets passing through the eliminator 19 is 10 μm or less. However, the water droplet diameter may be any water droplet diameter of 100 μm or less, and the water droplet diameter that passes through the eliminator 19 and is supplied into the bathroom is a bath. It is desirable that the water droplet size be enough to allow a person to take a bath without feeling a water droplet, and generally a water droplet size of about 10 μm or less allows most people to take a bath without feeling a water droplet. .

  Further, in the present embodiment, the plate heat exchanger 5 is used as the heat exchange means, but there is no problem even if other means are used as long as both heat exchanges can be efficiently performed. Even if a heat exchanger or the like of the formula is used, there is no difference in the operation effect.

  Further, in the present embodiment, the water supply is directly connected to the pipe as the liquid supply means. However, if it is desired to increase the water pressure, there is no problem even if the pressure is increased by a pump or the like. There is no difference in function and effect.

  Further, in the present embodiment, the thermal valve 27 is used as the opening / closing means of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24. However, other means can be used as long as the circuit can be opened and closed using some control means. Even if the electromagnetic valve 28 or the like is used, there is no problem in the effect. Desirably, a flow rate control valve capable of controlling the temperature and humidity by the control device 9 and having good response to the control signal is preferable.

  In this embodiment, the electromagnetic valve 28 is used as the opening / closing means of the water supply path 25. However, there is no problem if other means are used as long as the circuit can be opened / closed using any control means. Even if the valve 27 or the like is used, there is no difference in its effect. Desirably, a flow rate control valve capable of controlling the temperature and humidity by the control device 9 and having good response to the control signal is preferable.

(Embodiment 2)
Embodiment 2 of the present invention will be described below with reference to the drawings. The same parts as those in the conventional example and the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted.

  First, a schematic configuration of the bathroom sauna apparatus in the present invention will be described.

  FIG. 1 is a schematic diagram showing a schematic configuration of a bathroom sauna apparatus according to an embodiment of the present invention. As shown in FIG. 1, the bathroom sauna apparatus 1 includes an exterior body 2 and a front panel 3 that form an outer shell, a sauna module 4 that sucks air in the bathroom, heats and humidifies it, and then blows it back into the bathroom, and a plate heat exchanger 5. The ventilation unit 8 is provided on one surface of the exterior body 2 and connected to the opening 7 communicating with the air passage, and the control device 9 controls these components. Each specific configuration will be described below.

  As shown in FIG. 2, the front panel 3 that forms the bathroom side surface of the exterior body 2 is a suction port 103 for sucking air in the bathroom, and for blowing out the heated and humidified air to the outside of the bathroom sauna device 1. An air outlet 102 is provided. Moreover, the filter 10 is provided in the sauna module 4 side of the suction inlet 103, and it has the structure which prevents the penetration | invasion of a fine dust and dust when circulating the air in a bathroom. Further, a louver 11 for changing the blowing direction of the heated and humidified air is provided at the outlet 102, and the louver 11 is a louver connected to a control device 9 (not shown in FIG. 2). By operating freely by the drive motor 12, the blowing direction can be varied in an arbitrary direction.

  As shown in FIG. 3, in the sauna module 4, an air passage 104 that connects the suction port 103 and the air outlet 102 of the front panel 3 is provided, and a control provided on the air inlet 103 side of the air passage 104. Air is blown into the sauna module 4 by rotation of a cross flow fan 107 as a blowing means connected to a motor 13 whose rotation speed can be freely changed by a device 9 (not shown in FIG. 3). An upstream side of the cross flow fan 107 is provided with a coil 14 which is a heat exchanger for air heating as a heating means, and hot water is supplied to the coil 14 from a heat supply unit 6 (not shown in FIG. 3). By supplying, the air flowing in from the bathroom through the coil 14 is heated, and it becomes possible to blow hot air. A humidifying unit 15 is provided on the downstream side of the cross flow fan 107 in the air blowing path 104. Hot water (for example, 40 to 80 ° C.) is supplied from the heat supply unit 6 to the ejection nozzle 105 as a spraying means provided in the humidification unit 15, and the supplied hot water is sprayed from the ejection nozzle 105 as fine water droplets. At this time, the sprayed water droplet crushing unit 16 is provided in front of the spraying direction, and the sprayed water droplet is changed into a finer shape using the sprayed water droplet crushing unit 16. The sprayed water droplet crushing portion 16 has a shape having a gradient with respect to a horizontal plane when installed in the air passage. According to this shape, drainage is good, and excess water does not stay at the location where the hot water sprayed from the ejection nozzle 105 and the sprayed water droplet crushing portion 16 collide, so that the solid wall surface is exposed and disturbed by the excess water. Water droplets can be crushed without any damage. At this time, the larger the installation gradient, the better. However, it is desirable to ensure that a gradient of 5 ° or more is ensured, so that excess water at the collision portion between the sprayed hot water and the sprayed water droplet crushing portion 16 can be surely drained. It becomes. Since the surface of the sprayed water droplet crushing portion 16 is water-repellent with a silicon-based thin film formed thereon, the drainage performance is improved. Further, as shown in FIG. 9, since the sprayed water droplet crushing portion 16 has a shape in which a conical protrusion 38 having a radius of about 5 mm and a height of about 5 mm is raised from the crushing portion plane 17, the drainage performance is further improved. When hot water collides with the object 38, the degree of diffusion of the fine water droplets after the collision increases, and it becomes possible to carry more fine water droplets to the outlet 102. At that time, if the sprayed water droplet crushing portion 16 is vibrated by the ultrasonic oscillator, the relative speed between the sprayed water droplet and the sprayed water droplet crushing portion 16 is increased, and it is possible to crush the droplets into finer water droplets. Here, with respect to fine water droplets (for example, a water droplet diameter of 100 μm or less), the water droplets that are carried along with the air to be blown to the outlet 102 to humidify the interior of the bathroom and could not be crushed into fine water droplets, go to the drainage section 112 Head. Among the fine water droplets carried with the blown air, water droplets having a relatively large water droplet diameter (for example, a water droplet diameter of 10 to 100 μm) are collected by an eliminator 19 as a water droplet collecting means provided on the outlet 102 side of the humidifying unit 15. To the drainage section 112. Fine water droplets (water droplet diameter of 10 μm or less) that have passed through the eliminator 19 are supplied to the bathroom from the air outlet 102 together with the air heated by the coil 14, and heat and humidify the interior of the bathroom. The eliminator 19 is made of a coarse mesh material, and does not require a large-scale structure such as a meandering air passage using the conventional ventilation guide plate 113, and the pressure loss can be made relatively small. Moisture toward the drainage part 112 passes through the drainage pipe 20 connected to the drainage part 112 and is drained outside the apparatus. The drainage part 112 is provided at the lowermost part of the humidification part 15 and has a slope on the bottom surface so that the drainage pipe connection part becomes the lowermost end so that excess water does not stay in the humidification part. At this time, the larger the angle of the drainage gradient on the bottom surface, the better. However, it is desirable to ensure that the excess water in the humidifying section is drained by ensuring a gradient of 5 ° or more. Similarly, the drainage pipe 20 connected to the outside of the apparatus can be installed with an equivalent gradient of 5 ° or more to prevent the excess water from staying in the apparatus. Further, the drainage unit 112 is provided with a float switch 21. When the water level rise of the drainage unit 112 is detected and the predetermined water level is exceeded, the control device 9 stops the water supply to the ejection nozzle 105 to humidify. Water leakage from the part 15 is prevented.

  In the heat supply unit 6 shown in FIG. 5, the circulating hot water supplied from the heat source is branched by the branching unit 22 into two paths, a heating hot water circulation circuit 23 and a humidifying hot water circulation circuit 24. The heating hot water circulation circuit 23 is connected to the coil 14 and heats the coil 14. As shown in FIG. 6, the coil 14 includes a water pipe 29 through which the heating hot water supplied from the hot water circulation circuit 23 circulates, and a heat transfer fin 30 provided on the outer wall portion of the water pipe 29. The heat transfer fins 30 are heated by the high-temperature heating circulating hot water flowing through the water flow pipe 29, and air is circulated through the heat transfer fins 30 to exchange heat with the air to heat the air. The humidifying hot water circulation circuit 24 is connected to the plate heat exchanger 5 to heat the plate heat exchanger 5. As shown in FIG. 7, the plate heat exchanger 5 is configured by alternately arranging two paths, a high temperature side path 32 and a low temperature side path 33, which are blocked by the heat transfer wall 31. Heat is exchanged through the heat transfer wall 31 to heat the liquid on the low temperature side by circulating the humidified water used for humidification in the opposite direction in the low temperature side path 33 while flowing through the path 32. The circulating hot water that has exited the coil 14 and the plate heat exchanger 5 passes through the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 again and flows into the junction 26, and the circulating hot water that has joined the one path passes to the heat source. Then, it is heated again and the supply is repeated. The tap water supplied from the liquid supply means passes through the water supply path 25 and is connected to the low temperature side path 33 of the plate heat exchanger 5. The tap water exiting the plate heat exchanger 5 flows again into the ejection nozzle 105 through the water supply path 25. The tap water in the water supply path 25 that has been subjected to heat exchange and becomes high temperature is sprayed from the ejection nozzle 105 to form fine hot water droplets, and is blown into the bathroom together with the heated bathroom air. The hot water that has flowed into the coil 14 through the heating hot water circulation circuit 23 exchanges heat with the air in the bathroom that passes through the air passage 104 by the cross flow fan 107 inside the coil 14. Heats the interior of the bathroom by blowing out the air in the bathroom, which has become hot after heat exchange, into the bathroom. In addition, a thermal valve 27 for blocking the circulation is provided in the two flow paths of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24, and the flow rate of the circulating hot water flowing into the coil 14 and the plate heat exchanger 5 is provided. The amount of heating and humidification can be changed by adjusting. The thermal valve 27 is a valve that opens and closes the valve by increasing the temperature of the valve support connected to the valve body by supplying electric power and expanding and deforming the valve support. Further, an electromagnetic valve 28 is provided on the upstream side of the plate heat exchanger 5 on the water supply path 25, and the supply amount of the humidified water can be changed by controlling the opening and closing of the water supply. The electromagnetic valve 28 is a valve that opens and closes a valve that uses electromagnetic force by an electrical signal.

  The ventilation unit 8 shown in FIG. 8 includes a ventilation fan 34 for sucking in bathroom air into the ventilation unit 8 and an exhaust duct 35 which is an air exhaust path, and an opening provided on one surface of the exterior body 2. The part 7 and the opening 7 are connected via a damper 36 for changing the opening area. The damper 36 is normally closed during the sauna operation, but can be opened and closed by a damper driving motor 37 connected to the control device 9 (not shown in FIG. 8), and the ventilation fan 34 is rotated and the damper is rotated. By opening 36, the air in the bathroom is ventilated into the ventilation unit 8 from the suction port 103, and is ventilated from the exhaust duct 35 to ventilate the bathroom. The adjustment of the ventilation amount is performed by changing the opening area of the damper 36 and controlling the rotational speed of the ventilation fan 34, and a necessary ventilation amount is realized by a combination thereof.

  When the sauna operation is started, the motor 13 in the sauna module 4 is operated to rotate the cross flow fan 107, and the air in the bathroom is sucked from the suction port 103, passes through the air blowing path 104, and again enters the bathroom from the air outlet 102. The air in the bathroom circulates by flowing into the room. At that time, the thermal valve 27 that is an opening and closing means of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 and the electromagnetic valve 28 that is an opening and closing means of the water supply path 25 are opened, and heating and humidification are started in the apparatus. . At this time, the louver 11 provided on the front panel 3 is opened, and the blowing direction of the heated and humidified air is controlled. When a certain amount of time has elapsed and the temperature and humidity in the bathroom reach a predetermined value, the number of revolutions of the motor 13 is changed, and the amount of heating and humidification is changed. After that, when a certain amount of time has passed and the temperature and humidity in the bathroom exceed a predetermined value, the number of rotations of the motor 13 is changed to adjust the temperature and humidity in the bathroom, and the heating hot water circulation circuit 23 and the humidification hot water circulation are changed. The temperature and humidity in the bathroom are controlled by repeatedly opening and closing the thermal valve 27 provided in the circuit 24 and the electromagnetic valve 28 provided in the water supply path 25. When the sauna operation is stopped, the operation of the motor 13 in the sauna module 4 is stopped, and the thermal valve 27 provided in the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24 and the electromagnetic valve 28 provided in the water supply path 25 are provided. close. Thereafter, in order to perform ventilation operation for drying in the bathroom, the damper 36 provided at the connecting portion of the exterior body 2 and the ventilation unit 8 is opened, and the ventilation fan 34 in the ventilation unit 8 is rotated to rotate the bathroom sauna. The air in the bathroom that flows in from the suction port 103 of the apparatus 1 is discharged from the exhaust duct 35 to the outside of the bathroom.

  By performing the operation as described above, the inside of the sauna target room (bathroom) is in a high-temperature and high-humidity state (about 40 ° C./80%), and can be in a mist sauna state that encourages bathers to sweat. Become. In addition, by forming the humidifying unit 15 with the configuration as in the present embodiment, water droplets having a large diameter are collected and compared in the air passage 104 even without a large configuration like a conventional meandering air channel. Only small water droplets can be blown into the bathroom.

  In this embodiment, the sauna target room has been described as a bathroom. However, if the problem such as condensation in a high humidity space can be solved, the room is not limited to the bathroom, and a space dedicated to the sauna is used. Even if the configuration is provided separately, there is no difference in the function and effect.

  In the present embodiment, the motor 13 for driving the cross flow fan 107 is the motor 13 whose rotational speed can be freely changed by the control device 9, but can be changed to at least two kinds of rotational speeds. There is no need to make any difference in the effects. Desirably, the motor is preferably a motor that can linearly change the rotational speed to an arbitrary rotational speed. Further, when the operation is performed under constant conditions without changing various settings, there is no problem even if the motor is driven only at a constant rotational speed, and there is no difference in the operation effect.

  In the present embodiment, the air in the bathroom is blown into the air passage 104 using the cross flow fan 107 as the air blowing means. If the air flow, power consumption, noise, vibration, etc. are satisfied, the sirocco Even if it is a fan of another type, such as a fan, a turbo fan, or a propeller fan, there is no problem and no difference is produced in its operation effect.

  Further, in the present embodiment, the fin tube type coil 14 is used as a heating means for heating the blown air. However, there is no problem even if other heating means is used as long as the blown air can be sufficiently heated. Even if a heater or other heat source is used in front of the cross flow fan 107, there is no difference in the function and effect.

  Moreover, in this Embodiment, it was set as the structure which humidifies by spraying warm water in the humidification part 15, However When a bathroom is small (about 0.5 tsubos) and does not require so much humidification, it is normal temperature Even if tap water (about 20 ° C) is used, there will be no difference in its effects. Desirably, it will be ejected so that the bathroom has the desired temperature and humidity according to the size of the bathroom and the temperature atmosphere outside the bathroom. It is desirable to appropriately set the temperature of the humidified water ejected from the nozzle 105.

  Further, the sprayed water droplet crushing portion 16 has a shape in which a conical projection 38 having a radius of about 5 mm and a height of about 5 mm is raised from the crushing portion plane 17. However, after the hot water sprayed from the ejection nozzle 105 collides with the projection 38. As long as the diffusibility of the fine water droplets is improved, there is no problem even if other shapes are used, and even if the projections such as hemispheres and pyramids are raised, there is no difference in the effect.

  Further, in the present embodiment, the surface of the sprayed water droplet crushing portion 16 is made water-repellent by forming a silicon-based thin film, but surplus is present at the location where the hot water sprayed from the ejection nozzle 105 collides with the sprayed water droplet crushing portion 16. There is no problem even if other means are used as long as the water can be prevented from staying, and even if a method of forming a Teflon (registered trademark) -based thin film or a resin having water repellency is used, the effect is also achieved. Does not make a difference.

  In the present embodiment, the sprayed water droplet crushing unit 16 vibrates at a frequency of about 1 MHz to 3 MHz by the ultrasonic oscillator. However, if the water droplet can be crushed to the required size, the frequency within that range can be used. There is no problem even if other means are used, and even if a method using a motor or a linear drive method is used, there is no difference in the operation effect.

  In the present embodiment, the diameter of the water droplets passing through the eliminator 19 is 10 μm or less. However, the water droplet diameter may be any water droplet diameter of 100 μm or less, and the water droplet diameter that passes through the eliminator 19 and is supplied into the bathroom is a bath. It is desirable that the water droplet size be enough to allow a person to take a bath without feeling a water droplet, and generally a water droplet size of about 10 μm or less allows most people to take a bath without feeling a water droplet. .

  Further, in the present embodiment, the plate heat exchanger 5 is used as the heat exchange means, but there is no problem even if other means are used as long as both heat exchanges can be efficiently performed. Even if a heat exchanger or the like of the formula is used, there is no difference in the operation effect.

  Further, in the present embodiment, the water supply is directly connected to the pipe as the liquid supply means. However, if it is desired to increase the water pressure, there is no problem even if the pressure is increased by a pump or the like. There is no difference in function and effect.

  Further, in the present embodiment, the thermal valve 27 is used as the opening / closing means of the heating hot water circulation circuit 23 and the humidifying hot water circulation circuit 24. However, other means can be used as long as the circuit can be opened and closed using some control means. Even if the electromagnetic valve 28 or the like is used, there is no problem in the effect. Desirably, a flow rate control valve capable of controlling the temperature and humidity by the control device 9 and having good response to the control signal is preferable.

  In this embodiment, the electromagnetic valve 28 is used as the opening / closing means of the water supply path 25. However, there is no problem if other means are used as long as the circuit can be opened / closed using any control means. Even if the valve 27 or the like is used, there is no difference in its effect. Desirably, a flow rate control valve capable of controlling the temperature and humidity by the control device 9 and having good response to the control signal is preferable.

  As described above, the bathroom sauna apparatus according to the present invention is capable of obtaining sufficient humidification without causing a feeling of water droplets, and is used in combination with a device for ventilating and air-conditioning a room other than the bathroom to warm and humidify the room. It can be applied to the intended use.

Schematic diagram of bathroom sauna apparatus according to embodiments 1 and 2 of the present invention Front panel schematic Schematic which shows the sauna module part of the bathroom sauna apparatus of Embodiment 1, 2 of this invention Schematic diagram of the comb-shaped sprayed water droplet crushing part of Embodiment 1 of the present invention Heat supply part schematic diagram of Embodiment 1, 2 of this invention Coil schematic Schematic diagram of the plate heat exchanger Schematic diagram of the ventilation unit Schematic diagram of the sprayed water droplet crushing part with a raised protrusion Schematic showing a conventional bathroom sauna device

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Bathroom sauna apparatus 2 Exterior body 3 Front panel 4 Sauna module 5 Plate heat exchanger 6 Heat supply part 7 Opening part 8 Ventilation unit 9 Control apparatus 10 Filter 11 Louver 12 Louver drive motor 13 Motor 14 Coil 15 Humidification part 16 Spray water droplet Crushing part 17 Crushing part plane 18 Flat plate 19 Eliminator 20 Drain pipe 21 Float switch 22 Branch part 23 Heating hot water circulation circuit 24 Humidification hot water circulation circuit 25 Water supply path 26 Junction part 27 Thermal valve 28 Solenoid valve 29 Water pipe 30 Heat transfer Fin 31 Heat transfer wall 32 High temperature side path 33 Low temperature side path 34 Ventilation fan 35 Exhaust duct 36 Damper 37 Damper drive motor 38 Projection 101 Bathroom 102 Air outlet 103 Suction port 104 Air supply path 105 Injection nozzle 106 Water heater 107 Cross Flowa 108 warm air generator 109 case body 110 air communicating port 111 outlet communicating port 112 drain portion 113 ventilation guide plate 114 bypasses the mixing chamber

Claims (6)

A suction port for sucking in the air in the bathroom, an air passage for conveying the sucked air, an air blowing means for sucking and blowing air in the bathroom, and humidifying the air passing through the air passage In the bathroom sauna apparatus provided with a humidifying means for discharging the humidified air to the bathroom, the humidifying means humidifies the air by spraying humidified water onto the air passing through the air passage. The bathroom is characterized in that it is further refined by providing a sprayed water droplet crushing section for colliding water droplets after spraying in the humidifying water spraying direction in the humidifying means to make the water droplets finer. Sauna equipment. 2. The bathroom sauna apparatus according to claim 1, wherein the sprayed water droplet crushing portion is in a spraying direction of a spraying means, and the sprayed water droplet crushing portion has a shape having a gradient with respect to a horizontal plane. 3. The bathroom sauna apparatus according to claim 1, wherein the sprayed water droplet crushing portion is in a spraying direction of a spraying means, and the sprayed water droplet crushing portion has a comb-like shape. 3. The bathroom sauna apparatus according to claim 1, wherein the sprayed water droplet crushing portion is in a spraying direction of a spraying means, and the sprayed water droplet crushing portion has a shape in which a protrusion protrudes from a flat surface. The bathroom sauna apparatus according to claim 1, 2, 3, or 4, wherein the surface of the sprayed water droplet crushing part is water-repellent. 6. The bathroom sauna apparatus according to claim 1, wherein the sprayed water droplet crushing portion vibrates.

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